Instrument landing system



Jan. 28, 1947,. w. L. BARRow INSTRUMENT LANDING SYSTEM Filed Oct. 23, 1941 5 Sheets-Sheet 1 INVENTOR WILMER L. BARROW my r-:TA

w. L. BumeowJ 2,414,791 INSTRUMENT LANDING SYSTEM Filed oct. 2:5, .194i 5 sheets-sheet 2 .Farm 2, 1947. w. l.. BARRow 2,414,791

INSTRUMENT LANDING SYSTEM WILMER L. BAR ROW Jan. 28, 1947. w L, BARRQW 2,414,791

INSTRUMENT LANDING SYSTEM n Filed oct. 2s. 1941 5 sheds-sheet 4 FIG. Il

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INVENTQR WBLMER L. BARROW J. 28, 947. wI lBARRQW 2,414,791

INSTRUMENT LANDING SYSTEM Filed Oct. 23, 1941 5 Sheets-Sheet 5 MDJULA TED ANPL IF IE' R MODULA 7' 0H OJC/L LATDR osC/L LA ron PHASE .7H/F TER HODUL TED HPL IF IE R FROM AME 30 347 BACANcE FIG. l5

FILLED PHASE sHxTeR lNvl-:N'roR WILMER L. BARROW employing the same.

Patented Jan. 28, 1947 UNITED STATES PATENT 2,414,791 INSTRUMENT LANDING SYSTEM Wilmer L. Barrow, Newton, Mass., assignor to Sperry Gyroscope Company, Inc., Brooklyn, N. Y., a corporation of New York This invention relates, generally, to the blind landing `oi? aircraft by radio means, and the invention has reference, more particularly, to a novel overlapping beam type of instrument landing system in which the signal transmitted from the ground or other landing area and received vat the aircraft is designed to provide in the craft suitable control voltages or currents such as an audio frequency voltage or current of reversing phase character. Such a signal is suitable for use in a servo-controlling device which controls the landing of the aircraft and in actuating indicating instruments useful as aids in landing aircraft. 1

Inthe overlapping-beam instrument landing systems of `the prior art, two or more beams are transmittedv to provide an equi-signal course along which the plane should fly in-order, safely and properly', to carry out an instrument landing. In these prior-art systems, it has been customary to modulate each of the two or more beamsat distinct and different audio frequencies; for example, 90 and 150 cycles, etc.. a second. Further characteristics of these prior-art systems include separation of lter circuits in the re- 4 ceiver that separate into distinct circuits the received signal from each of the two or more beams', and indicating devices that operate by virtue of the difference of intensity of the signals thus separated. It is also customary, in most of the prior art systems, alternately to transmit on one beam and then the other, in order to avoid effects of `interference in space by the two beams of the same carrier frequency. This commutation of thefa'rrier necessitates the use of more or less complicated equipment and in addition generally lowers the operating eiliciency of the systems Further, these prior art systems generally were not readily adaptable for automatic control of the aircraft.

One object of the present inventionis to provide a novel overlapping beam type of instrument landing system employing ultra high frequency transmitter means feeding directive radiators to transmit simultaneously a plurality of overlapping beams, one or more pairs of which beams are used for directing the craft in one or more planes, and at least one of which beams is used to provide a reference signal.

Another object of the invention is to provide a receiver on the craft adapted for receiving said beams and utilizing the same for establishing the degree of deviation of the craft from itstrue course in'- any desired plane or planes, said re- 2 ceiver producing a variable magnitude, reversible phase signal suitable for control purposes.

Still another object of the invention is to provide means for utilizing the output of said receiver for controlling servo means effecting automatic control of the craft.

Another object of the present invention is to provide a novel beam type of instrument landing system of the above character wherein the ultra high frequency transmitter means employs an audio frequency or servo-signal modulation superimposed on a radio frequency modulation to 'make possible a separate reception of the indieating or servo-signal from the reference signal, which has the same audio frequency and must be transmitted independently on the craft to protide the necessary phase reference required by said indicating or servo-signal electrically controlled equipment. said reference signal modulation being superimposed on a different radio frequency modulation from the servo-signal, thus providing distinct channelswhich may be filtered in the receiver means and independently demodulated.

Another object of the present invention is to provide a novel beam type of instrument landing system of the above character wherein, for guidance in a single spacial coordinate. an oscillator means applies an ultra high frequency to a radio frequency modulated power amplifier means, the output of which is fed to two frequency multiplier means which are in turn preferably modulated in phase opposition by a servo frequency, the resultant outputs being applied to two directive radiators to form overlapping guide beams, while concomitantly the reference beam is produced in a similar manner but modulated by a different radio frequency and by the same servo frequency in xed phase relation to said aforementioned servo frequencies.

Still another object of the invention is to provide signal modulation means consisting of turna-ble baffles or vanes insertable in the path of the electromagnetic radiation, as in a wave guide or radiator.

Another object of the present invention is to provide a novel beam type of instrument landing system of the above character wherein, for guidance in both coordinates, an oscillator means app'lies an ultra high frequency to a power amplier'. the output of which is fed to three high frequency multiplier means. each multiplier being modulated by a. separate radio frequency, resulting in three separate frequency channels feeding individual wave guides. two of which guides are divided into two sections each, the amplitude of said frequency channels being caused to bemodulated Yby paddles or vanes, situated in said four divided guide sections and in one undivided wave guide, as said paddles are rotated or turned on a common axis by a motor.

Still another object of the pre'sent invention is to provide a novel beam type of instrument landing system of the above character wherein, for obtaining guidance in both coordinates, commutation is employed to feed, in' proper sequence, the necessary radio frequency and servo frequency modulations to an ultra high frequency amplier means, the output of .which is applied l to an antenna or other radiator supplying a turnable parabolic reector 'or other directive means, whose axis of symmetry is slightly tilted with respect to its turning axis, said reflector turning synchronously with said commutation, thus producing in succession the necessary guide beams properly orientated in space, while concomitantly the reference beam is separately radiated;

Other objects and advantages willbecome apparent from the specification. takenin connection with the accompanying drawings, whereinthe invention is embodied in concrete form.

In the drawings,

Fig. 1 is a block diagram of a transmitter of this invention suitable for producing the desired beams in either azimuth or elevation.

Fig.'2 is a diagram of a receiver suitable for changing right-left and/or up-down information, as received from two transmitting systems such as the one shown in Fig. 1, into servo signals for operation of the control surfaces of the aircraft by means of a conventional'servo-system and/or for operation of indicating instruments.

Fig. 3 shows the plan view of the three' beams required for control in any one coordinate.

Fig. 4 shows the character of the modulation applied to these three beams.

Fig. 5 shows the variation of the final direct the servo-system as a function of the angular deviation of the aircraft from the xed flight path.

Fig. 6 shows a cross section of the ive beams 4` i current output of the receiver used in controlling Fig. 10 shows, an alternate transmitter system V which affords control in one coordinate.

Fig. 1l. shows a 'transmitter system which af- `fords control in both coAordinates.

Fig. 12 shows a detail of a modulating device used in the radiating horns of Fig. 11.

Fig. 13/ shows an elevationl of parabolas and their relative orientation, as used in a transmitting system such as that of Fig. 10.

Fig. 14 shows an alternate commutated system using a single rotating onset parabola to yprovide the f our overlapping beams necessary.

`Fig. 15 illustrates an electric servo device adaptedfor use in lconnection with the structure of Fig. 2.

Referring now to Fig. '1, a block or functional diagram is illustrated of the instrument landing system as pertainsto one coordinate or plane.

The transmitting source I is a 'frequency sta-` bilized radio-frequency oscillator of conventional type, whose frequency, after multiplication by the ultra high frequency multiplier amplifiers 2, 3 or 4,. becomes a frequency-which is of the order of 3x10B cycles per second Sand which may be designated as w and is useful in this invention' because plier amplifiers 2 and 3 may be modulated by a frequency (of the order of, say 300 kilocycles), i another frequency a l.(oif the order of. say 60 cycles). The modulation a appliedfrom oscilla tor 8 has-=0, where p is the phase; this signal, combined with p1 in modulator 6 is referred to as p12-0. The useful side bands supplied by multiplier i.l are vthen wtplian. The modulation a applied from oscillator 9 has 4 =180; this signal, combined with 1 in modulator 1 is referred to as 'B,iu`1s. The useful side bands emitted by multiplier 3 are then w- L-lialo.

The frequency. o emitted by multiplier amplifier 4 is modulated by a frequency p2 (of the order of say kilocycles) f the a frequency. The modulation a applied from oscillator I5 has f =4 n which may have lany-fixed phase relation to the outputs of oscillators 8 and 9; this signal. combined with B2" in modulator oscillator I4 is referred to as pziaR. The doubly modulated carrier emitted by multiplier 4 is then wzL-pzzaa.

The three signal channels, wrll-ao. wilialao, and linz- Lan are fed through Wave guides I I, III and I8; to radiators I2, I3, and I1, respectively. These ratdiators are shown as horns but may be any of the well known types of directive radiators. The radiators I2 and I3 are so orientated relative to each other that the characteristic overlapping-beam radiation pattern consisting of beams I8 and I9 (see Fig. 3) is produced, whereas radiator I1 produces a wide beam 20 containing both beams I8 and I9. These beams are transmitted continuously, and the lower frequency e of modulation of the three beams is the same. The phase of the three modulations is such that when the envelope of one beam has its maximum, that of the second preferably 'has its minimum, while the envelope of the thirdor reference beam, whose phase is the reference, may be similar to -one of the above or at an intermediate value.

Two distinct pairs of overlapping beams IB, I9 and I8', I9' (see Fig. 6) are employed as follows: one pair I8', I9' displaced angularly from each other in a vertical plane intersect along an inclined line producing the desired flight path to give altitude ,or glide path information to the craft; and the other pair I8, I9 displaced angularly from each other in a transverse plane, also intersect along said inclined line to give lateral or runway localizer information to the craft. These two sets of beams together provide continuous indication of the relative position of the plane with respect to the reference landing path in space that intersects the runway at its leading-or approach edge.

Thus,` two'of the systems shown in Fig. 1 would be necessary .for the complete system described above. A cross-section of the five beams necessary being shown in Fig. 6. The beams have the following frequencies:

Obviously, the same an signal can be used for both coordinates.

Suppose we consider again the right-left signal generation system as shown in Fig. 1. If, for example, the'radiators I2 and I3 are to supply this right-left signal, then Fig. 3 shows the horizontal patterns of the radiation elds, curve I8 indicating the pattern from radiator I2, curve I5, that from radiator I3, and curve 20, that from radiator I1.

According to the above description, antennas I2 and I3 transmit overlapping beams in which the indicating or servo-signal modulation ao, am is superimposed on the relatively high frequency modulation of frequency from modulator 5. The purpose of the modulation oscillator 5 is to make possible a separate reception of the servosignal, i. e., the vector sum of a0 and am which may be designated as aP, of the overlapping beams I8 and I9 from the reference signal R' of beam 20, which has the same frequency as the servosignal and which must be transmited to the craft also. In the functional diagram shown in Fig. 1, the separate transmission of the servo and reference signals is provided by means of the two distinct double modulations of frequencies 431 and ,82. Appropriate equipment, to be described, in the receiver separates p1 and its servo signal modulations from [32 and its reference signal modulations.

Fig. 4 illustrates the relation of a modulating voltages of the outputs of antennas I2, I3, and I1, respectively; the upper diagram showing the phase of the modulation on beam I8, the middle diagram, the a modulation of beam I9; this being of opposite phase; and the lowest diagram showing the phase of the reference modulation on beam 20.

The operationof servo-signal electrically controlled equipment of this invention requires the use of the aforesaid servo voltage and the steady reference voltage of identical frequency. The

`reference voltage is to be continuously supplied to servo apparatus of a balanced rectifier or similar type in order to provide a direct current output whose amplitude and polarity vary with the magnitude and phase, respectively, of the servo sigf nal aP. The pattern 20, representing the reference beam is preferably made broad to supply said reference voltage at all positions of the craft in space at which the servo-signal may be received. Frequencies and e2 are chosen to make modulation simple and to make easy the separation of servo and reference signals in the receiver, as determined by the details of the equipment employed and the state of theart.

Fig. 2 illustrates practical `receiver equipment for this blind landing system. The energy received, contains the following frequencies, for a five lbeam system, i. \e., wavrliaw wzL-BZULR, ampara?, where we denoted ao, also by a?, and is picked up by antenna 2|, then amplified and demodulated by ultra high frequency receiver 22. The output of receiver 22 consists of ,Bliapzi-aw siap resulting from the above-described modulation processes. The output of the receiver 22 is separated into three different circuits by means of the separation lters 23, 24 and 25. Filter 23 selects ,Sli-P and rejects all other signals. The second separation lter 24vv passes ,S2-rap..

third filter 25 passes signals of ,Baia-P. The three lters are followed by demodulators 26, 21 and 28 whose output will contain currents of frequency a only.

The outputs of the .demodulators 26, 21 and i 28 are amplified by means of power amplifiers 29, 30, and 3|, respectively.' A cathoderay indi.

The l cator 82 of the type disclosed in applications Serial No. 101,274, filed September 17, 1936, by F. Moseley, for Aircraft flight indicator and control system therefor, and Serial No. 378,030, filed February 8, 1941, by E. Norden, F. Gemmill and E. Isbister for Aircraft flight indicator and system, is connected to the outputs'of the above amplifiers. A balanced rectier 33 is supplied with ap by amplifier 29 and ap by amplifier 30. The varying direct current signal from 33 travels through leads 38 to operate a motor 31. 'Ihe motor 31 actuates a. conventional hydraulic servo system consisting of a sensitive valve 38, a power cylinder 39, and. transmission cables 40 to control a vertical rudder surface 4|. Another balanced rectifier 34 is supplied with ap and an by amplifiers 3| and 30, respectively. 'I'he leads 35 from this rectifier 34 may be used to operate a similar servo system to turn the horizontal control surfaces of the craft.

If desired, instead of using a hydraulic servo system for operating the rudder 4| or elevator, as the case may be, the same may be operated by an electric/servo system as shown in Fig. 15.

In this system the balanced rectifier 34 is connected through the two outer leads 35 to the grids of grid controlled rectifier tubes and |50'. A local alternating current supply |5| feeds a voltage through transformer |52 to the plates of tubes |50 and. |50' in phase opposition, while this supply acts through a network |53, central lead 35, a divided resistor |54, and by way of the outer leads 3.5 to apply a phase shifted bias voltage to the grids of the tubes |50 and |50'. This bias voltage is displaced approximately 180 with respect to the alternating current plate voltage.

When the output signal ap is of one phase corresponding to the location of the craft in\the lower lobe I8 of Fig. 6, for example, then this signal will put a positive voltage on the grid of, say,

tube |50 at the same time that its plate swings y plied with current in phase with the supply |5|.

Thus the motor |51 operates in one direction to actuate control surface |58 in the proper manner to effect an upward movement of the craft I toward the intersection of beams I8' and I9'.

If the craft were in beam I9', the lower tube |50' would be caused to pass current thus effecting rotation of the motor |51 in the reverse direction as will be apparent. The ,greater the magnitude of the signal voltage, the greater the resultant motor speed will be, so that the motor speed and hence the rate of movement of the craft back to the desired glide'path is substantially proportional to its deviation from this path. In order to prevent hunting of the craft about the desired glide path, an anti-hunt circuit may be used employing a generator |59 driven by motor |51 and supplying a velocity voltv age through a lead to the input of power amplifier 3| in opposition to the signal voltage The output of the demodulator 26 provides the servo voltage whose frequency is ae and whose phase is either or 180 depending on which side of the true glide path the crai'tis located, and whose amplitude will vary with the rightleft position in spaceof the receiving equipment. l'I'he amplitude will increase with the 'angular deviation from the equi-signal path for signals up to a certain value, after which it will gradually reduce to ze'ro for continued deviation. The output of the demodulator 21 comprises the reference voltage of frequency an, of constant reference phase and substantially constant amplitude as provided by appropriate volume controls or by automatic volume control. The outputof the demodulator 28 provides the servo voltage whose frequency is again up. whose phase is either 0 or 180, 'and whose amplitude will vary with the up-down position in space of the receiver.

Consideration of the system as described above should make it appear that the demodulated output from demodulators 26 and 28 will have a zero value, both as to amplitude and phase, when the aircraft is disposed along the equi-signal path, indicated in Fig. 3 for one coordinate by 0:0. When the receiving apparatus is at a position indicated in Fig. 3 by 0:01, the strength of signal from beam I8 is greater than that of beam I9. Consequently, there will be an alternating current output from demodulator 26 whose phase is 0 and whose amplitude, over a relativelybroad angular range, will be roughly receiving equipmentis placed in the angular positions 0=01 of Fig. 3, the signal received from beam I9 will predominate over that of beam I8; the output'of demodulator 26 will thencomprise an alternating current of 180 phase and of amplitude also roughly proportional to the angular deviation -0. Figs. 7, 8 and 9 indicate, by means of rotating vector diagrams, the three situations just described, wherein Vp indicates the outputvoltage of demodulator 26.

As above described, two pairs of beams will beI `may be necessary, one of which is tuned to the `localizer transmitter and the other to the glidepath transmitter. To make one of the receivers required for a two separate receiver system, the

channel consisting of lter 25, demodulator 28,

and power ampliiler 3| would be omitted from the receiver of Fig. 2.

Inasmueh as a two coordinate system' requires a minimum of three signal channels, only two modulations, for example., ,82 and p3, are necessary to separate these channels at the receiver; In this case one channel will be in the form wiel., so that filter 28 would pass aP, rejecting all other frequencies. and demodulator 26 would be eliminated. In general, if n is the number of channels employed, the minimum number of modulations necessary lis (1t- 1).

Fig. shows a diagram of the variation of the direct current output of the balanced rectiers 33 and 34, as a measure of the angular deviation -of the plane from its proper course. When on 4proportional to the angle 0. Similarly, when the course. there is zero current a negative angular deviation, causes an increase in the plus sense, and a positive angular deviation an vincrease in the negative sense o1' the current. Over a reasonable range the change in current is roughly proportional to the angular deviation. Buch direct current characteristics are admirably suited to cathode ray or meter indication or to the operation of electrical machinery, hydraulic machinery through electro-hydraulic interconnections, and to combination with Vother signals or take-oil currents in the craft.

Fig. 10 illustrates in detail a transmitter suitable for use in one coordinate. A quartz crystal oscillator 42 supplies a stabilized frequency to a vacuum tube multiplier 43. The output of multiplier 43 supplies two modulated power amplifiers 44 and 46. Ampliers 44 and 45 are modulated by modulation oscillators 48 and 41 with frequencies ma and The output of the modulated power amplifier 44 with a frequency is fed by coaxial leads 54 andj55 to multipliers 1|5 and,16 of the type disclosed in Ycopending application, Serial No. 416,170, for Ultra high frequency electron discharge tubes, led October 2'3, 1941. The-outputs of tubes 15 and 'I6 are further modulated by the relative low a frequency which is supplied from modulation oscillator 66 through phase Shifters 61 and 68 and leads 10 and 'II to modulating grids 80 and 19 of tubes I6 and 15 in 180 out-of-phase relation. The doubly modulated outputs of tubes 15 and 16 after amplification by amplifiers 49 and 5I are supplied through lines 51 and 58 to the radiators 63 and f 64 whose reectors I 2f and I3' produce the desired overlapping beams as shown vin Figs. 3 and j(i. The output of amplifier 45 as modulated by 1 y E092) is applied to a. frequency multiplier 11 which is supplied with the an modulation by means ot iQ-1) y through. vcoaxial lines 88, 89 and 90 to frequency multipliers 9|, 92,93, respectively. lThe multiplier 9| is modulated by a. frequency supplied by an oscillator 91 to grid, 94, the multiplier 92 by im.) t

supplied by an oscillator 98 to a grid 3l, and the multiplier 93 by y supplied by an oscillator 93 to a grid 36. Multipliers 6|, 92. 93 then feed wil, wl-, wl-s through concentric lines |00, |I, |02, to wave guide portions |20, |2I, |22, respectively. Wave guide portions |20, |2I, |22 are shown as having matching lplugs |03, |04, |05, respectively, and coaxial lines |00, |0| |02 may have matching plugs |06, |01, |08,respectively. Wave guide portion |20 divides into two sections. feeding horns (or other radiators) I2" and I3". Similarly, wave guide portion |22 divides into two sections, feeding radiators ||2 and ||3. Wave guide |2| connects with radiator l1". Mounted-in the |4| to an antenna |36 which is mounted stationary in a parabolic reflector |35, the focus of which is slightly displaced with respect to the antenna |36 itself. A motor |30, through geardivided sections of the wave guides and |22 and in the undivided wave guide I2| are paddles |03, ||0, |09. ||0', and respectively, on a common shaft ||`5 which is turned by a motor I|4 at a revolutions a second. These paddles or bailies alternately open and close their associated wave guides, thus modulating the ow of radia- 'tion with a periodicity equal to the speed of rotationlor oscillation of the paddles. Fig. 12 shows the orientation of these paddles relative to shaft ||5, to which they are all attached, this ilxed orientation thus producing a fixed time relationship between the motion of the paddles and the time of superposition of the dierent modulations so that, for illustration, atthe moment that the ultra high frequency wave passing through horn l2" is at full amplitude the ultra. high frequency wave passing through horn I3" is at its minimum amplitude. Paddles |09 and |09 in wave guide sections leading to radiators I2" and II2, respectively, produce a0 modulation. Paddles ||0 and ||0' iniwave guide sections leading to radiators I3" and H3, respectively, cause an also modulation. Paddle in the Wave guide |2| gives the radiation from radiator I1" and an modulation. The output of horns I2" and I3" is then wiliao and wilials respectively. 'I'hese two beams may be used for right-left indication. The radiation from horns |I2 and |I3 is wisiao and artigiano. This channel may be usedv for up-down indication in the air-- craft. Radiator I1" emits a reference channel wiziR.

Fig. 13 shows a typical arrangement of the ra- I diators ||2', II3, |2', I3 and I1 associated with the complete system of Fig. 10, the radiators ||2' and |I3 being used for producing the elevational lobes.

The .radiators may be mounted in a frame ||3 mounted onV trunnions turnably supported on posts IIB, carried by a movable truck IIB. A similar arrangement may be used in connection with the structure of Figs. 1 and 11. The radiation from these parabolas or horns is as follows:

Fig. 14 represents a two coordinate;l system using commutation to feed, in proper sequence, a0, 90, 1180, am, ,81, and s' to a modulator |31. A stabilized oscillator |20 supplies a carrier w to modulated amplifiers |,2I and |22. The modulated ampliiler I2| feeds through a concentric line ing |32 and a. hollow shaft |33 rotates the parabola |36, thereby rotating the focus of this re- `ilector around the antenna |36 in such a manner that the principle axis of the beam describes a cone andthe intensity on the axis of rotation is not zero at any position, as well as operating an am, generator |23, an o generator |24, and the contact arms of four-segment commutators |26, |26, |21.

One output of the am, generator is connected to the left and right segments of commutators |26 and |21, respectively, while the other output terminal is led to the right and left contacts of |26 and |21, respectively. One side of the output of the a0 generator goes to the upper and lower segments of commutators |26 and |21, respectively, while the other side of the a0 generators output is applied to the lower and upper portions of |26 and |21, respectively. The a0 generator also supplies an to the modulated amplifier |22 through a phase shifter |40. One terminal of a oscillator is connected to the upper l. and lower contacts of the commutator |25, while one terminal of a B3 oscillator feeds the right and left segments of commutator |25. Oscillators |38 and |33 have a common lead with the modulator |31. The modulator |31 is fed appropriate q and frequencies through the brushes of commutators |25, |26, and |21, and supplies the modulation products to the modulated amplifler |2| where a modulation of the carrier w takes place. An oscillator |22 supplies a frequency to the modulated amplifier |22 whose output is fed through a coaxial line |42 to an antenna |44 in a reflector |43. This radiation is the reference channel wiiaR.

. 90 could also be obtained lfrom generator |24 andaphase shifter.

When all the contact arms are vertical, the output of antenna |36 is wiliao. If the parabola rotates in a clockwise direction as one y faces the parabola, then when the contact arms al1 point to the right the antenna output is wiliam. When the contact arms point to the left the parabola output is farisei-MW also and am exist because the arms |26 and |21 have reversed the connections to ,generator |23 and |24 as the parabola has rotated through 180.

Thus, all the necessary guide beams are produced during each revolution of the commutator contact arms, each beam radiating during somewhat less than a quarter cycle of the sweep frequency which may be made any convenient value.

As many changes could be made in the above construction and many apparently widely different embodiments of this invention could .be made without departing from the scope thereof, it is prising a separation modulation and a signal modulation of the same frequency as said rstmentioned signal modulation but of substantially 180 differing phase position, means for modulating another portion of said high frequency current with a double modulation comprising a separation modulation of a different frequency from said aforementioned separation modulations and a reference frequency of the same frequency as said signal modulations, means for projecting the high frequency currents containing the signal modulations into space in the form of two overlapping lobes of electromagnetic radiation and means for projecting that portion of the high frequency current modulated with the reference modulation into space in the form of a lobe of electromagnetic radiation that overlaps both of said other lobes of electromagnetic radiation, the character of said modulations and the disposition of said lobes being such that said path is a locus of equisignal strength relative to said lobes which dene the flight path.

2. Apparatus as defined in claim 1 comprising turnable baille means positioned within said electromagnetic radiation projecting means for producing said signal and reference modulations.

3. In apparatus of the character described means for generating high frequency energy, a radiator of electromagnetic energy, conduit means for supplying said high frequency energy to said radiator, and movable baille means positioned for controlling the flow f said high frequency energy through' said conduit means and from said radiator for effecting modulation of said energy.

4. Apparatus for deiining a flight path axis or the like comprising a source producing a carrier wave of ultra high frequency, means providing a plurality of separate output channels from said source, means for modulating the waves in the respective channels with signals of intermediate frequency, means for further modulating the modulated waves in said channels with signals of relatively lower frequency but differing substantially 180 in phase in the respective channels, and means for directionally radiating the doubly modulated waves from each channel in such manner that said axis is a locus of equisignal strength relative to said waves.

5. In the apparatus dened in claim 4, means providing a third output channel for said carrier wave, means for modulating the carrier wave in said thirdchannel with a signal of a frequency different from said intermediate frequency, means further modulating said modulated carrier wave in the third channel with a signal of said relatively lower frequency but of diierent phase than the phases in said first two channels.

6. Apparatus for defining the coordinates of a flight path comprising a source producing a carrier wave of ultra lhigh frequency, means prof. viding three separate output channels from said source, means for modulating the carrier waves in each of said channels with signals all of different frequency, and means for further modulating said modulated waves with signals of a still further different frequency, said last named means alsorembodying means for providing a constant reference phase in the output of one of said channels and related phases in the other two channels, the path defined by said coordinates being of equisignal strength relative to said modulated waves.

7. Apparatus as defined in claim 6, wherein said means for further modulating the modulated waves comprises mechanically actuated bafiles located in thedifferent wave guides.

8. In a method of determining direction, the steps of radiating into space at least five overlapping lobes of energy having a selected ultra high frequency, modulating the waves in each of said lobes, further and dierently modulating selected pairs of said modulated waves by signals of a relatively lower frequency but substantially 180 apart in phase, directionally radiating all of said lobes in such relation as to establish a selected directional pathV which is a locus of equisignal strengthcwlth respect to all the lobes.

9. Radio apparatus for directing a mobile craft comprising means for radiating partially overlapping radio beams containing a common carrier frequency, means for modulating said beams with a signal in out of phase relationship to establish an equi-signal plane in space, means for radiating a radio wave distinguishable from said overlapping beams, and means for modulating said radio wave with an audio wave synchronized with said signal to provide ,a phase reference in space serving to determine Ifthe direction of departure of said craft from said equi-signal plane.

10.. 'Radio apparatus for directing a mobilecraft comprising means for radiating apair of partially overlapping radio beams having a common carrier frequency, means for modulating said beams with an audio frequency signal substantially in phase opposition to establish an equi-signal plane in space, means for radiating a radio wave receivable independently of said overlapping beams,` and means for modulating said radio wave with said audio frequency signal to provide a phase reference in .space serving to determine the direction-of departure of said craft from said equisignal plane.

l1. Radio apparatus for directing a mobile craft comprising means for radiating a pair of partially overlapping radio beams having a common' carrier frequency, means for` modulating said beams with WILMER L. BARROW.

Certificate of Correction Patent No. 2,414,791.

WILMER L. BRROW It is hereby certified that errors appear in the printed specification' of the above numbered patent requiring correction as follows: Column 4, line 18, for B1 read 1;1ine 32 for ratdiators read radiators column 6, line 9, for aP after and read an; column 10, line 48', after output is" insert wgi; aiago also when the contact arms point down, the parabola output is; and that the said Letters Patent should be read with these corrections therein that the same may conform to the record of the case in the `Patent OHice. 'v

Signed and sealed this 22nd day of July, A. D. 1947.

y [am] LESLIE FRAAZER,

First Assistant 'ommzssoner of Patemts.Y

January 28, .1947.- 

